Opasnet base structure: Difference between revisions

Latest revision as of 12:01, 10 January 2014

This page is a knowledge crystal of subtype variable. The page identifier is Op_en1913
Moderator:Jouni (see all)
Citation of this page: Juha Villman, Einari Happonen, Jouni T. Tuomisto: Opasnet Base structure. Opasnet 2010. [1]. Accessed 21 Nov 2024.
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This page is about the old structure of Opasnet Base used in ca. 2008-2011. For a description about the current database, see Opasnet base 2.

Question

Opasnet Base is a storage and retrieval system for results of variable and data from studies. What is the structure of Opasnet Base such that it enables the following functionalities?

Storage of results of variables with uncertainties when necessary, and as multidimensional arrays when necessary.R↻
Automatic retrieval of results when called from Opasnet wiki or other platforms or modelling systems.
Description and handling of the indicess that a variable may take.
It is possible to protect some results and data from reading by unauthorised persons.
If is possible to build user interfaces for easily entering observations into the Base.

Answer

Opasnet base is a MySQL database located at http://base.opasnet.org.

Data structure

Main article: Data structures in Opasnet

All data should be convertible into the following format:

			Observation
Year	Sex	Age	Height	Weight	Description
2009	Male	20	178	70	An optional column for descriptive text about each row.
2009	Male	30	174	79
2010	Male	25	183	84
2010	Female	22	168	65

where

Names of explanation columns, also known as indices.

Explanation data, also known as locations. You can use these columns as search criteria.

Observation index, typically called "Observation". Common name for all observation columns

Names of observation columns. These are the parameters of interest.

Observation data. These are the actual measurements.

Table structure in the database

All tables

act
Uploads, updates, and other actions
Field	Type	Null	Extra	Key
id	int(10) unsigned	NO	auto_increment	PRI
acttype_id	tinyint(3) unsigned	NO		MUL
who	varchar(50)	NO
comments	varchar(250)	YES
time	timestamp	NO
temp_id	int(10) unsigned	NO		MUL

actloc
Locations of an act
Field	Type	Null	Extra	Key
actobj_id	int(10) unsigned	NO		PRI
loc_id	int(10) unsigned	NO		PRI

actobj
Acts of an object
Field	Type	Null	Extra	Key
id	int(10) unsigned	NO	auto_increment	PRI
act_id	int(10) unsigned	NO		MUL
obj_id	int(10) unsigned	NO		MUL
series_id	int(10) unsigned	NO		MUL
unit	varchar(64)	YES

acttype
List of action types
Field	Type	Null	Extra	Key
id	int(10) unsigned	NO	auto_increment	PRI
acttype	varchar(250)	NO		UNI

cell
Cells of an object
Field	Type	Null	Extra	Key
id	int(12) unsigned	NO	auto_increment	PRI
actobj_id	int(10) unsigned	NO		MUL
mean	float	YES
sd	float	NO
n	int(10)	NO
sip	varchar(2000)	YES

loc
Location information
Field	Type	Null	Extra	Key
id	int(10) unsigned	NO	auto_increment	PRI
std_id	int(10) unsigned	NO		MUL
obj_id_i	int(10) unsigned	NO		MUL
location	varchar(100)	NO
roww	mediumint(8) unsigned	NO
description	varchar(150)	NO

loccell
Locations of a cell
Field	Type	Null	Extra	Key
cell_id	int(10) unsigned	NO		PRI
loc_id	int(10) unsigned	NO		PRI

obj
Object information (all objects)
Field	Type	Null	Extra	Key
id	int(10) unsigned	NO	auto_increment	PRI
ident	varchar(20)	NO		UNI
name	varchar(200)	NO
objtype_id	tinyint(3) unsigned	NO		MUL
page	int(10) unsigned	NO
wiki_id	tinyint(3) unsigned	NO

objtype
Types of objects
Field	Type	Null	Extra	Key
id	tinyint(3)	NO		PRI
objtype	varchar(30)	NO

res
Result distribution (actual values)
Field	Type	Null	Extra	Key
id	bigint(20) unsigned	NO	auto_increment	PRI
cell_id	int(12) unsigned	NO		MUL
obs	int(10) unsigned	NO
result	float	NO
restext	varchar(250)	YES
implausible	binary(1)	YES

wiki
Wiki information
Field	Type	Null	Extra	Key
id	tinyint(3)	NO		PRI
url	varchar(255)	NO
wname	varchar(20)	NO

Contents of selected tables

Table objtype
id	objtype
1	Variable
2	Study
3	Method
4	Assessment
5	Class
6	Index
7	Nugget
8	Encyclopedia article
9	Run

Table acttype
id	acttype
1	Start object
2	Finish assessment
3	Update formula
4	Upload data (replace)
5	Upload data (append)
6	Review scope
7	Review definition
8	Add object info

Rationale

Data

Software

Because Opasnet base will contain very large amounts of mostly numerical information, the state-of-the-art structure is a SQL database. Because of its flexibility, ease of use, and cost, MySQL is an optimal choice among SQL software. In addition to the database software, a variable transfer protocol is needed on top of that so that the results of variables can be retrieved and new results stored either automatically by a calculating software, or manually by the user. Fancy presenting software can be built on top of the database, but that is not the topic of this page.

Storage and retrieval of results of variables

The most important functionality is to store and retrieve the results of variables. Because variables may take very different forms (from a single value such as natural constant to an uncertain spatio-temporal concentration field over the whole Europe), the database must be very flexible. The basic solution is described in the variable page, and it is only briefly summarised here. The result is described as

  P(R|x₁,x₂,...)

where P(R) is the probability distribution of the result and x₁ and x₂ are defining locations of an index where a particular P(R) applies. Typically locations are operationalised as discrete indices. A variable must have at least one index. Uncertainty about the true value of the variable is operationalised as a random sample from the probability distribution, in such a way that the samples are located along an index Sample, which is a list of integers 1,2,3...n, where n=number of samples.

Old description of the structure

Dependencies

Replacing some cells

It is possible that there is a large data, where there is a need to update only a few cells while all others remain the same. How should this be done? There are a few potential alternatives.

Use the current replace functionality. Replace all cells but most of them with the original value.
Use a new act_type that is similar to the current append functionality. This should be understood in a way that if there are two (or more) identical cells (based on cell indices and locations), then the newest result is used and all older ones are discarded. (If the old append is used, then new info is just seen as a new row in the data table, not a replacement of an existing row.
Add a new field into the cell (?) table with an updated cell_id (in a similar way than act_id and series_id are used in the actobj table). This way, the new cell can automatically inherit all locations of the old cell.

Formula structure

Now it has become clear that it is not enough to have samples of the result distributions. It must be possible to completely recalculate the result based on the information in the Opasnet Base. There are different approaches:

Calculate the result based on a formula that may refer to other variables called parents. This is a deterministic approach.
Calculate the result based on the marginal distribution and (conditional) rank correlations with parent variables. This is a probabilistic approach.

This approach requires new tables, namely Formula and Language.

----11: . Do we need tables DIF and DIP like Uninet? --Jouni 21:50, 30 December 2009 (UTC) (type: truth; paradigms: science: comment)

DIP
- DIP_node_id
- DIP_parent_node_id
- DIP_corr_coeff
- DIP_parent_index
DIF
- DIF_node_id
- DIF_formula
- DIF_varnames_in_formula

Universal Opasnet Base

The idea of universal Opasnet Base says that it should be possible to store results in such a way that the results themselves are public but their interpretation is limited. For example, patient symptoms and clinical test results should be openly available for research, but information about whose results they are should be private. This can be achieved with the following database structure.

Let's say that it is enough to have two security levels, public and private. A person wants to record personal health information into the database. She logs in with her personal user name. The private profile gives the name (say, Liisa) and social security number of the person, while the public profile says only "30-40-year-old woman in Finland". Liisa writes down her symptoms or medical information and saves them. This is what is stored in the databases:

**Information stored in the public and private databases. The private database can read tables from the public one but not vice versa.**
Table, field	Private database	Public database
act.who	Liisa, 010175-1024	Woman, 30-40 a
act.when	2011-03-09 22:09:10	2011-03
obj.name	N/A. Data is taken from public side.	Pregnancy test
loccell.loc_id (locations and indices explained)	Person = 010175-1024 Time = 2011-03-09 Test = Clearblue digital test	Age = 30-40 Sex = Female Country = Finland Time = 2011-03 Test = Clearblue digital test
res.restext	N/A. Data is taken from public side.	Pregnant 1-2 weeks.

Based on the information, anyone can see that there is a woman in Finland who has used a Clearblue pregnancy test and the result was positive. But there is no way an outsider could connect this information to any particular person, because all information that could be used for linking is located in the private website. However, an authorised person from health case could see the data in the private database and connect Liisa and the test result.